JP2010182576A - Flat cable with shield - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide FFC (Flexible Flat Cable) structure capable of securing bendability while controlling desired impedance, and excellent in high speed transmission. <P>SOLUTION: This flat cable 1 with a shield has a cable part 7 laminated by sandwiching a plurality of conductors 3 juxtaposed substantially parallel with insulators 5 from both sides, terminal parts exposed with the plurality of conductors 3 are provided in both end parts of the cable part 7, and surfaces of the insulators 5 in the both sides of cable part 7 are coated with a conductive sheet. The cable part 7 composed of divided cable parts 7A partitioned with a slit substantially parallel to the conductors 3 between the conductors 3, and the shield 17 for coating every divided cable part 7A. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a shielded flat cable (FFC or FPC), and more particularly to a shielded flat cable that achieves both impedance control and improved transmission characteristics and bending characteristics.

  In recent years, electronic devices such as flat-screen televisions typified by household appliances have been improved in functionality, and display with high fineness has become possible. Along with this, the transmission speed has been increased, and a cable capable of high-speed transmission has become necessary. That is, since the transmission frequency has been increased due to the increase in transmission capacity and transmission speed, control of the characteristic impedance of the cable is very important. Impedance control for matching this impedance to a certain value is possible by adjusting the distance between the shield and the conductor, the dielectric constant between the conductor and the shield, and the conductor dimensions.

  In addition, since the above electronic devices are rapidly becoming smaller, lighter, and thinner, a flexible flat cable (hereinafter referred to as “FFC”) having flexibility is often used.

  The FFC is an insulator such as a resin sheet from both sides of a plurality of conductors arranged in parallel because it is required to have high flexibility to be used inside an electronic device and to be connected to a connector. It is a flexible cable that is inserted into a tape.

  Referring to FIGS. 5A to 5C, for example, the FFC 101 is laminated by sandwiching a plurality of flat conductors 103 arranged in parallel with each other with insulating tape 105 (insulator) from both sides. At both ends of the laminated cable, terminal portions 107 are provided by peeling the insulator 105 and exposing the plurality of flat conductors 103. The terminal portion 107 is provided with a reinforcing plate 109 for defining a terminal thickness required for insertion into the connector and reinforcing the terminal.

  Further, the shielded FFC 111 is an insulator of the FFC 101 similar to that shown in FIGS. 5A to 5C in order to prevent electrical signal noise inside the equipment as shown in FIGS. A shield 113 made of a metal foil tape is bonded to the surface of 105. Further, in this shielded FFC 111, one of the rectangular conductors 103 is a GND line, and the GND line and the shield 113 are electrically connected. Other than that is the same as FIG. 5 (A)-(C). For example, Patent Documents 1 and 2 correspond to the shielded FFC 111. FIG. 6C shows a state in which the insulating tape 105 on the GND line as in Patent Document 2 is removed, and the shield 113 and the GND line are electrically connected with the conductive adhesive 115.

  As described above, the impedance control needs to adjust the distance between the shield 113 and the flat conductor 103, the dielectric constant, and the dimensions of the flat conductor 103, but the dimensions of the flat conductor 103 must be fitted to the connector. It cannot be adjusted to. Therefore, items that can be adjusted due to the fitting problem with the connector are the distance between the shield 113 and the flat conductor 103 and the dielectric constant between the flat conductor 103 and the shield 113.

  If the space between the shield 113 and the rectangular conductor 103 is widened or the dielectric constant is lowered, the impedance increases. On the contrary, when the space between the shield 113 and the rectangular conductor 103 is reduced or the dielectric constant is increased, the impedance is lowered. Specifically, for example, a method of decreasing the dielectric constant by increasing the thickness of the insulator 105 or covering the surface of the insulator 105 with a foamed resin insulator 105 as disclosed in Patent Document 2. There is.

  For example, in order to set the differential impedance to 100Ω, in the shielded FFC 111 in which the rectangular conductors of 0.035 × 0.3 mm are arranged at intervals of 0.5 mm, the thickness of the insulating tape 105 having a dielectric constant of 2.4 Needs to be 0.43 mm or more. Considering that the insulating tape 105 (insulator) of the normal FFC 101 is 0.06 mm, it is expected that the shielded FFC 111 having the matched impedance is thick and hard.

  Moreover, in patent document 3, the slit which is not shown in parallel with the said flat conductor is put between the several flat conductors of FFC similar to FFC101 of FIG. 5 (A)-(C), and the flexibility of a cable is increased. ing.

  Moreover, in patent document 4, it is bending by flattening the thickness of the flat conductor only of the bending part of FFC similar to FFC101 of FIG. 5 (A)-(C), and making it thinner than the terminal part of both ends. The characteristics are improved.

Japanese Patent Laid-Open No. 04-272617 JP 2003-31033 A JP 2003-22713 A Japanese Patent No. 3037444

  By the way, in the conventional shielded FFC 111, when the thickness of the insulator 105 is increased in order to control the impedance, the insulator 105 becomes harder as the thickness increases, so that the flexibility is impaired. .

  In order to improve the flexibility of the shielded FFC 111, it is necessary to use a soft material for the FFC 111 or to make the FFC 111 itself a soft structure.

  In order to soften the material of the FFC 111 itself, it is conceivable to increase the foaming degree of the insulating tape 105 (insulator) with something other than the flat conductor 103. However, considering the mechanical strength of the insulating tape 105 (insulator), there is a limit to increasing the foaming degree. The same applies to the case where the surface of the insulator 105 is covered with the foamed resin insulator 105 as in Patent Document 2.

  On the other hand, in order to improve flexibility and flexibility, Patent Document 3 discloses a method in which a slit is formed. In Patent Document 4, the thickness of a flat conductor 103 having only a bent portion is flattened to obtain terminal portions at both ends. In either case, impedance matching and transmission characteristics are not taken into consideration.

  An object of the present invention is to provide an FFC structure that ensures flexibility while controlling a desired impedance and is excellent in high-speed transmission.

In order to solve the above problems, the shielded flat cable of the present invention has a cable portion in which a plurality of conductors arranged in parallel in parallel are sandwiched by insulators from both sides, and the cable portions are provided at both ends of the cable portion. In a flat cable with a shield provided with a terminal part exposing the plurality of conductors and covering the surfaces of the insulators on both sides of the cable part with a shield,
The cable portion is composed of a divided cable portion in which the conductors are separated by a slit substantially parallel to the conductor, and a shield that covers each of the divided cable portions.

  In the shielded flat cable of the present invention, in the shielded flat cable, it is preferable that two pairs of conductors are wired in each of the divided cable portions.

  In the shielded flat cable of the present invention, in the shielded flat cable, it is preferable that two divided conductors and a ground wire are wired in each of the divided cable portions.

  In the shielded flat cable of the present invention, it is preferable that the ground wire is electrically connected to the shield in the shielded flat cable.

  Further, in the shielded flat cable of the present invention, in the shielded flat cable, each divided cable portion is preferably laminated and assembled in a state of being twisted by approximately 90 ° with respect to the conductor arrangement direction in the terminal portion. .

  As can be understood from the means for solving the problems as described above, according to the present invention, each divided cable portion is separated from each other by the signal line and the shield of the other divided cable portion. No longer receive. As a result, it was possible to provide a shielded FFC that secured flexibility while controlling a desired impedance, and was excellent in high-speed transmission.

1 shows a shielded FFC according to a first embodiment of the present invention, in which (A) is a plan view, (B) is a sectional view taken along line IB-IB in (A), and (C) is ( It is sectional drawing of the arrow IC-IC line of A). FIG. 2 shows a shielded FFC according to a second embodiment of the present invention, in which (A) is a plan view, (B) is a cross-sectional view taken along line IIB-IIB in (A), and (C) is ( It is sectional drawing of the arrow IIC-IIC line | wire of A). It is a top view which shows FFC with a shield of 3rd Embodiment of this invention. FIG. 4 is a plan view showing a state in which a plurality of split cable portions of the shielded FFC of FIG. A conventional FFC is shown, (A) is a plan view, (B) is a cross-sectional view taken along the line VB-VB in (A), and (C) is a view taken along the line VC- in (A). It is sectional drawing of a VC line. The conventional shielded FFC is shown, (A) is a plan view, (B) is a sectional view taken along the line VIB-VIB in (A), and (C) is a view taken in the direction of arrow VIC-VIC. It is sectional drawing of a line.

  Embodiments of the present invention will be described below with reference to the drawings.

  Referring to FIGS. 1A to 1C, a shielded flexible flat cable 1 (hereinafter simply referred to as “shielded FFC”) according to the first embodiment includes a plurality of arrays arranged in parallel. For example, it has a cable part 7 in which a flat conductor 3 as a conductor is laminated with an insulator 5 from both sides. At both ends of the cable portion 7, there are provided first and second terminal portions 9, 11 that peel the insulator 5 and expose the plurality of flat conductors 3. The first and second terminal portions 9 and 11 are provided with a reinforcing plate 13 for defining a terminal thickness required for insertion into the connector and reinforcing the terminal. The plurality of conductors are not limited to the flat conductor 3 described above, and may be conductors having a circular cross section or other cross sectional shapes.

  Further, the cable portion 7 is a portion excluding the first and second terminal portions 9 and 11 and the reinforcing plate 13, and is partitioned between the flat conductors 3 by slits 15 substantially parallel to the flat conductors 3, A plurality of split cable portions 7A are formed. In each divided cable portion 7A, the surface of the insulator 5 is bonded with a conductive sheet 17 as a shield, for example, and covered with a shield. Here, the conductive sheet 17 is a sheet provided with an insulating resin layer on one surface of a metal sheet and an adhesive layer on the other surface.

  In the above-described shielded FFC1, in order to perform differential transmission in order to improve transmission characteristics, for example, signal lines as two conductors to be paired are wired to each divided cable portion 7A. That is, each divided cable portion 7A is formed by dividing the cable portion 7 by the slit 15 so that signal lines and signal lines are combined and wired.

  Accordingly, each of the divided cable portions 7A is separated from each other by the signal line and the power supply line of the other divided cable portion 7A and the conductive sheet 17 independently of each other, so that each pair of differential signals is independent from the outside. Unaffected. By separating the signal lines 3 with the slits 15, even if a low-speed signal or a power supply line is mixed in one FFC, noise hardly occurs, and the shielded FFC 1 suitable for high-speed signals is obtained. In terms of flexibility, since the slits 15 are provided in parallel to the rectangular conductor 3, each divided cable portion 7A has an independent structure, and the width of each divided cable portion 7A having this independent structure is also reduced. improves.

  Next, a shielded FFC 19 according to a second embodiment of the present invention will be described with reference to the drawings. The same members as those of the shielded FFC 1 of the first embodiment described above are denoted by the same reference numerals, and detailed description thereof is omitted.

  Referring to FIGS. 2A to 2C, the shielded FFC 19 of the second embodiment is different from the shielded FFC 1 described above in terms of the position of the slit 15 and the configuration wired to each split cable portion 7A. Is a point.

  That is, the shielded FFC 19 has, for example, two signal lines and two ground lines 21 as a pair of conductors 3 in each split cable portion 7A in order to perform differential transmission in order to improve transmission characteristics. Wired. In other words, each divided cable portion 7A is formed by dividing the cable portion 7 by the slit 15 so as to be wired in combination in the order of the ground line 21, the signal line 3, the signal line 3, and the ground line 21. . In each of the divided cable portions 7A, the surface of the insulator 5 is bonded with a conductive sheet 17 and covered with a shield.

  The operation and effect are the same as those of the shielded FFC 1 of the first embodiment described above. Further, the conductive sheet 17 is electrically connected to the GND line 21 to enhance the shielding effect. For example, in FIG. 2C, in a sheet provided with an insulating resin layer on one side of the metal sheet of the conductive sheet 17 and an adhesive layer on the other side, a conductive resin is used for the adhesive layer and the upper insulating layer is used. The metal sheet is electrically connected to the GND line 21 through the GND line 21 from which the layer has been removed and the conductive adhesive 22, thereby enhancing the effect as a shield.

  Next, a shielded FFC 23 according to a third embodiment of the present invention will be described with reference to the drawings. The same members as those of the shielded FFC 1 of the first embodiment described above are denoted by the same reference numerals, and detailed description thereof is omitted.

  3 and 4, the shielded FFC 23 according to the third embodiment performs differential transmission in order to improve transmission characteristics. Therefore, each split cable portion 7A has a pair of rectangular conductors. The cable portion 7 is formed by dividing the cable portion 7 with slits 15 so that 3 is combined and wired as a signal line / signal line. In each divided cable portion 7A, the surface of the insulator 5 is wrapped with a conductive sheet 17 and covered with a shield. Here, three divided cable portions 7A are formed.

  Next, as shown in FIG. 4, each of the three split cable portions 7A is rotated by twisting approximately 90 ° with respect to the arrangement direction of the flat conductors 3 in the first and second terminal portions 9 and 11, respectively. Thus, the laminated assembly portion 27 is formed by stacking and assembling (bundling) the three divided cable portions 7A so as to overlap each other and fixing them with a fixing tool 25 such as an adhesive tape.

  Thereby, the width direction of the lamination | stacking gathering part 27 is 2.25 mm, and the height direction of a lamination | stacking becomes 1.5 mm. Therefore, the width of the split cable portion 7A of the shielded FFC 23 (that is, the width of the stacked assembly portion 27) is reduced. Thus, by inserting the slit 15 in the cable portion 7, the shape of the shielded FFC 23 can be flexibly changed, so that wiring in a space-saving manner is also possible. Conventionally, the FFC has a wide width so that it can pass even in a narrow place that cannot be passed.

  For example, in FIG. 3, the width of the eight rectangular conductors 3 is 40 mm (two are removed to insert the slits 15), and the thickness is 0.75 mm to make the differential impedance 100Ω.

  In the third embodiment, the row of the plurality of flat conductors 3 in the cable portion 7 is divided into three, and the two flat conductors 3 paired with each split cable portion 7A are the signal line 3 and the signal line 3. However, as in the second embodiment, the two signal lines 3 and 3 and the two ground lines 21 that are paired with each divided cable portion 7A are wired. Even applicable.

  From the above, it was possible to ensure flexibility (flexibility) while controlling desired impedance by forming slits 15 in the cable portion 7 to form a plurality of divided cable portions 7A. In addition, by arranging the flat conductors 3 so that the signal lines form a pair and inserting a slit 15 for each of the flat conductors 3 forming a pair of differential signals, noise from the conductor 3 of the other adjacent divided cable portion 7A. And an FFC structure excellent in high-speed transmission could be provided.

  As described above, the shielded FFC has been described in the embodiment, but the present invention can be similarly applied to a shielded FPC (flexible printed circuit).

1 FFC with shield
(Shielded flexible flat cable)
3 Flat conductor (conductor, signal line)
5 Insulator 7 Cable Part 7A Split Cable Part 9 First Terminal Part 11 Second Terminal Part 13 Reinforcing Plate 17 Conductive Sheet (Shield)
19 Shielded FFC (of the second embodiment)
21 Ground line 23 FFC with shield (of the third embodiment)
25 Fixing device 27 Laminated assembly part

Claims (5)

A cable portion in which a plurality of conductors arranged in parallel in parallel are sandwiched by insulators from both sides, and a terminal portion that exposes the plurality of conductors is provided at both ends of the cable portion. In a shielded flat cable with the surface of the insulator on both sides covered with a shield,
The flat cable with shield, wherein the cable portion includes a divided cable portion in which the conductors are divided by slits substantially parallel to the conductor, and a shield that covers each divided cable portion.   The shielded flat cable according to claim 1, wherein two conductors to be paired are wired in each of the divided cable portions.   2. The shielded flat cable according to claim 1, wherein a pair of two conductors and a ground wire are wired in each of the divided cable portions.   4. The shielded flat cable according to claim 3, wherein the ground line is electrically connected to the shield.   4. The shielded flat cable according to claim 1, wherein each divided cable portion is laminated and assembled in a state of being twisted by approximately 90 ° with respect to the conductor arrangement direction in the terminal portion.

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